Conservation requires rapid action to be effective, which is often difficult because of funding limitations, political constraints, and limited data. Turtles are among the world’s most endangered vertebrate taxa, with almost half of 356 species threatened with extinction. In Australia’s Murray River, nest predation by invasive foxes (Vulpes vulpes) was predicted to drive turtle declines in the 1980s. We assessed populations of the broad-shelled turtle (Chelodina expansa), eastern long-necked turtle (C. longicollis), and Murray River turtle (Emydura macquarii) in the Murray River and some of its associated waterways. Our results suggest that the predicted decline is occurring. All three species are rare in the lower Murray River region, and were undetected in many locations in South Australia. Moreover, E. macquarii had considerable population aging almost everywhere, possibly due to comprehensive nest destruction by foxes. Chelodina longicollis also had population aging at some sites. Sustained low recruitment has potential to lead to collapses as turtles age, which is particularly worrying because it was predicted over 30 years ago and may have already occurred in South Australia. Our results show that turtle declines were not mitigated since that prediction. If the crash continues, a vertebrate guild responsible for considerable nutrient cycling in the aquatic ecosystem will disappear. Our results highlight a worst-case outcome when species declines are predicted, but insufficiently mitigated.
Earth’s sixth mass extinction is currently under way1,2,3,4. Although a number of mechanisms exist for predicting species’ extinction risks due to varied threats5,6, the complex synergies that drive extinction severely hamper our ability to protect declining species7. However, conservation success depends on rapid action8. Here, we describe the ongoing decline of a freshwater turtle community. The decline was first predicted over 30 years ago9, and we show that subsequent mitigation has been inadequate to prevent it.
Worldwide, about half of the 356 extant turtle species are listed as vulnerable or worse by conservation agencies10. Adult turtles are overharvested for both human consumption and the pet industry11,12, can experience high road mortality13,14, and are killed by human-introduced predators when they nest or disperse10,15. Turtles are struck by boats16, drowned in fishing nets and other human structures17,18, and wounded or killed by anglers19,20. Mortality of eggs and young has also increased, primarily because of poaching and predation by introduced predators9,21,22. Humans introduce turtles into novel ecosystems, which can lead to hybridization and genetic introgression23,24, and competition with native species25. Finally, novel diseases have potential to cause rapid extinctions, as nearly occurred in the Bellinger River snapping turtle (Myuchelys georgesi) in 201526,27,28, and may be occurring in other species29,30.
In addition to acute threats, turtles are susceptible to environmental degradation. Increasing global temperatures may drive changes in population sex ratios in species with temperature-dependent sex determination31. Drought may cause both reduced breeding success and outright population declines in freshwater turtles in both North America and Australia32,33. These threats may be exacerbated by water flow regulation and extraction34. Increased salinization of freshwater habitats during droughts is especially dangerous for some species35,36. As long-lived species, often with catholic diets, turtles bioaccumulate high contaminant loads in polluted systems37,38, potentially with reproductive consequences39,40. Urbanization and habitat fragmentation increase turtle mortality41,42. Furthermore, even when threats to turtles can be mitigated, recovery is often slow43, due to long generation times and high rates of attrition at egg and juvenile life-stages44. Indeed, a recent study found no recovery in a Chelydra serpentina population that suffered mass mortality in the 1980 s45.
In Australia, about half of the 25 extant species of freshwater turtle are currently listed as vulnerable, endangered, or critically endangered. Invasive predators have been highlighted as a primary threat. More than 30 years ago, exceptionally high rates of nest predation by invasive red foxes (Vulpes vulpes) were predicted to drive freshwater turtle declines in the Murray River9. Foxes destroyed such large numbers of turtle nests (>93% per year) that juvenile recruitment was reduced to nearly zero, and only adult turtles remained abundant within the population9. Management of invasive predators has thus been one of the primary mechanisms for preventing turtle declines in Australia15,22,44,46. However, its effectiveness has not been comprehensively assessed. Only one study33 has compared turtle populations in the Murray River (Chelodina expansa, Chelodina longicollis, and Emydura macquarii) at multiple timepoints. Its results are alarming, as abundances of C. longicollis and E. macquarii declined by 69–91% between 1976 and 2011, and juvenile proportions of turtle populations plummeted33. However, this study was conducted at only at a few sites in south-central New South Wales and it is unclear whether the declines are consistent along the entire Murray River catchment.
Here, we report a rapid assessment of turtle populations throughout the southern Murray River catchment. Our aim was twofold: (1) to establish a baseline understanding of current turtle population status throughout the southern Murray River catchment, including identifying likely “hotspots” of turtle declines for future study and management actions; and (2) to identify geographic trends in turtle population status that could lead to focused hypothesis tests on the causes of any identified turtle declines. We assessed populations of all three species native to the river system, including the broad-shelled turtle (C. expansa), eastern long-necked turtle (C. longicollis), and Murray River turtle (E. macquarii).
We used a dual approach to test for differences in population status across the Murray River catchment33. First, we used catch-per-unit-effort (CPUE) as an index of relative abundance of each turtle species. We assume that sites with a low CPUE are sites where turtle densities are lower, whereas sites with high CPUE are sites where turtle densities are higher. Second, we tested for population differences in the proportions of juvenile and large adult turtles. Here, we used size as an index of age, such that large adults should be relatively old, and juveniles should be young. We followed Chessman33,47 in setting the maximum sizes (straight carapace length; SCL) for juvenile turtles: 220 mm for C. expansa, 180 mm for C. longicollis, and 190 mm for E. macquarii. We arbitrarily considered turtles with SCLs larger than 350 mm for C. expansa, 230 mm for C. longicollis, and 250 mm for E. macquarii to be “large” adults. Chessman33 and Thompson9,48 argued that the proportion of juveniles was an indicator of recent recruitment, whereas the proportion of large adults could indicate population aging. Thus, populations dominated by large adults likely experience low recruitment, and are potentially at risk of collapse when those turtles die of old age. In contrast, populations with large numbers of juveniles experience relatively high levels of recruitment and may have a lower risk of collapse.
Throughout the study, we caught 36 C. expansa, 251 C. longicollis, and 815 E. macquarii. Recapture rates were low, and we recaptured only two C. expansa, eight C. longicollis, and 18 E. macquarii. However, we re-captured one E. macquarii four times at Lake Mulwala. In South Australia, we captured 8 E. macquarii that appeared to be marked from previous studies, but never re-captured these subsequently.
CPUE and numbers of turtles caught varied across the southern Murray River catchment within each species (Table 1, Fig. 1). Because we accounted for trapping effort in each of the following analyses, we focus only on CPUE in our results, from here forward. Despite species-specific statistical patterns in our results, CPUEs of all three species were generally highest in the mid-Murray region (River Distance ~1500–2000 km), which corresponds to north-central Victoria and south-central New South Wales (Fig. 1). In C. expansa, CPUE was low across all sites (Fig. 1), but significantly increased with increasing distance from the river mouth (Fig. 2A; Table 1). CPUE of C. expansa did not differ with any other factor tested (Table 1). The relationship between CPUE and river kilometre was not retained when we removed sites with low or high trap effort (Table S1).
Chelodina longicollis CPUE significantly increased with increasing distance from the Murray River, and these relationship varied across wetland types (Fig. 2B; Table 1). Specifically, C. longicollis CPUE was higher in pond habitats than in all other types of habitats (Tukey P < 0.05; Fig. 2B). After removal of low-trap-effort sites the relationships between CPUE and distance from the Murray River were no longer significant (Table S1). However, there was still a significant difference in CPUE among wetland types (Table S1), and ponds had higher mean CPUE than did lakes, streams, and lagoons (Tukey P < 0.05), but not tributaries or backwaters (Tukey P > 0.05).
Emydura macquarii CPUE was generally higher than for the other two species (Fig. 1), and varied across wetland types and with river distance (Table 1). Specifically, CPUE increased with increasing distance from the river mouth (Fig. 2C). After accounting for river distance effects, mean E. macquarii CPUE was lower in ponds and streams than in all other habitats (Fig. 2C; Tukey P < 0.05). Unlike the CPUE results for the other turtle species, the statistical results for E. macquarii were not affected by the removal of sites with low or high trap effort (Table S1).
Proportions of juvenile and large adult turtles varied among wetland types and species. We caught C. expansa in sufficient numbers (at least five) to be included in our analysis at only five locations (Fig. 1), so we did not analyze C. expansa size structures. Two of these sites (tributaries at Echuca and Wentworth) had no obvious bias to juveniles or large adults. Two sites (Reedy and Cockatoo lagoons) had juvenile proportions of 22.2% and 50.0%, respectively. Reedy Lagoon also had 11.11% large adult females, and a backwater at Shepparton had 16.7% large adult females.
Numbers of juvenile and large adult C. longicollis differed uniquely across wetland types, and both increased as the total number of turtles caught increased (Table 2; Fig. 3A). We caught significantly more large adults than juveniles in pond wetlands (Tukey P < 0.05), but there were no significant differences within any other wetland type (Fig. 3A). Juveniles were also rare in backwaters and streams, but the numbers of large adults in these wetland types varied widely across individual sites (Fig. S2). No other factors were significant (Table 2).
In E. macquarii, numbers of juvenile and large adult turtles also varied uniquely among wetland types, and both increased with the total number of turtles caught (Table 2). We caught significantly more large females than juveniles within both backwaters and lagoons (Tukey P < 0.05; Fig. 3B). We also caught more large females than large males within lagoons (Tukey P < 0.05; Fig. 3B). There were no within-habitat differences in the numbers of large male, large female, or juvenile turtles in lakes or tributaries (Fig. 3B), and no other factors were significant. Large females were common at almost all sites we trapped (Fig. S3), but backwaters and lagoons had very high proportions of large adult females (Fig. 3B). Juveniles were rare across all sites, but were relatively common in lakes (Fig. 3B). Large males were consistently distributed throughout all wetland types (Fig. 3B). Notably, locations and wetland types with high proportions of large females, as a consequence, had low proportions of males of all sizes, which may indicate a sex-ratio bias towards females, especially in backwaters and lagoons. We did not catch enough E. macquarii in stream or pond wetland types to include them in this analysis.
Australia is now at the stage where the effects of invasive species and habitat destruction are being observed through species declines and extinction events. Across Australia, nearly half of all turtle species are listed as vulnerable or worse by state or federal agencies49. Turtle declines of up to 91% have been observed in sections of the Murray River33. A recent novel disease has also caused the near-extinction of an Australian freshwater turtle (Myuchelys georgesi), and may be a symptom of deteriorating water quality and climate change28. Here, our results provide further evidence that freshwater turtle populations in southern Australia are declining.
Catch-per-unit-effort data indicate that overall turtle abundance decreases as the Murray River approaches the ocean. Notably, we caught zero or very few turtles of any species at several locations in South Australia, including Calperum Station, Ramco Lagoon, and Currency Creek. Turtle numbers (relative to trapping effort) were higher in the mid- and upper-Murray regions. However, 10 of the sites where we caught zero turtles of any species were far upstream on the Murray River or its tributaries, and were much colder and faster flowing than other sites. These locations may not be suitable for turtles due to their ectothermic physiology. Even at the sites nearby where we did catch turtles, CPUE of E. macquarii was always low, possibly because our trapping exceeded their current range and extended beyond their preferred habitats50. By contrast, C. longicollis was occasionally very abundant in upstream, rocky stream sites, so it is unclear whether we extended beyond their preferred range or whether they are present but only at low densities at the sites where they were not captured.
Emydura macquarii are relatively abundant in some habitats in the mid-Murray region, but their numbers (relative to trapping effort) drop precipitously further downstream. In 8 of 10 sites in South Australia, we caught fewer than 10 E. macquarii, despite trapping efforts that were consistent with, or even exceeded, those further upstream. All of these downstream sites were near to other locations where we caught turtles, are well within the reported range of E. macquarii, and many probably supported large turtle populations in the past48. Across our study, E. macquarii was most abundant in backwater, lagoon, lake, and tributary habitats connected or close to the main channels. The habitat associations we detected largely follow the published preferences of the species50,51.
Chelodina longicollis exhibited higher mean CPUE in ponds disconnected from the main channel than in other sites. In addition, CPUE increased with increasing distance from the Murray River, but this relationship was not robust and disappeared when we removed sites with very low and high trapping effort from our statistical model. Low CPUE close to the river may indicate that the species has declined close to the river33,44. However, our results are also consistent with the species’ reported ecology. Chelodina longicollis has a broad distribution across the region and is not as tied to permanent water as are other species of turtles50. It prefers temporary wetlands in much of the Murray catchment, and is also found in both temporary and permanent wetlands far from the larger rivers of the region50. It is capable of migrating long distances overland to access/emigrate from ponds as they fill or dry52,53. Thus, C. longicollis may still be present in relatively high numbers farther from the river. Whether the differences in CPUE that we detected are due to its habitat preferences or localized declines is unclear, but a long-term comparison does support the hypothesis that a decline may be occurring in the mid-Murray33.
Chelodina expansa CPUE was low across the entire catchment, and increased with increasing distance from the Murray mouth. The latter trend was not statistically robust, but we caught only one individual in all trapping downstream of Mildura, VIC. Chelodina expansa was recently present in this region34,36, so our data may reflect our comparatively low sampling effort. We also focused primarily on wetlands adjacent to the river, and did not trap in the river itself, where C. expansa may be more abundant34,36. We caution that C. expansa’s historically low density also means that even proportionally large declines could be difficult to detect. Thus, although C. expansa may not have declined in the mid-Murray, it may have always been present in relatively low numbers. Sites where we caught the highest numbers of C. expansa again reflect previously-published habitat preferences50,51, including backwaters and lagoons with direct connections to the main channel of the Murray River.
The results of our analyses on the proportions of juveniles and large adults within turtle populations are striking, particularly for E. macquarii. Even in the habitat types where E. macquarii is most abundant, large adult females (>250 mm SCL), on average, account for the largest proportion of the population. Thus, most E. macquarii populations are strongly biased to large adult females. In contrast, juveniles made up very small proportions of most populations, which suggests that recruitment rates have been very low in recent years. Our observation of low juvenile numbers is similar to those reported in other demographic studies of E. macquarii9,33, and highlights that many populations of E. macquarii are aging. The trend is possibly a result of ongoing, consistently high rates of nest predation by foxes, which may nearly eliminate juvenile recruitment15,22,54. Population aging may also be caused by other factors that reduce recruitment but have not yet been investigated in turtles. The southern Murray catchment is heavily impacted by altered flow regimes55 and invasive carp56. Resulting changes water turbidity and macrophyte abundance have been linked to changes in E. macquarii diet57, and we suspect that the loss of macrophytes might also increase predation of hatchling and juvenile turtles by fish and wading birds. Regardless of the cause, our results suggest that ongoing, consistent low recruitment may drive turtle declines in the Murray River, which could lead to a population collapse across the catchment9,48.
Several locations are clear exceptions and exhibit relatively high rates of juvenile recruitment. Lake Eppalock on the Campaspe River, Lake Meran, Serpentine Weir on the Loddon River, and Clayton Bay at Lake Alexandrina all exhibited relatively high numbers of juvenile E. macquarii. All but Lake Meran also exhibited low numbers of turtles caught, and relatively low CPUE. Lake Eppalock, Lake Meran, and Serpentine Weir experienced complete or near-complete drying during the Millennium Drought58,59,60,61. Near Clayton Bay, an infestation with the Australian tubeworm (Ficopomatus enigmaticus) was reported in the Lower Lakes region in 2008. This emergent condition in turtles is due to high water salinity, which occurred during the Millennium Drought35. The worms form calcareous tubes on a range of artificial and natural surfaces and restrict the ability of turtles to swim effectively. Either complete drying or tubeworm encrustation could have killed a number of adult turtles at these sites, which may account for our low CPUE. Interestingly, comparisons of turtle body size against published growth-curves62 indicate that the juvenile turtles caught at these sites hatched since the end of the drought in 2010.
Assuming that fox predation on turtle nests is a major driver of the low numbers of juveniles we observed15,22,54, it is possible that the Millennium Drought caused such severe crashes in the adult E. macquarii populations at these locations that their nests are difficult for foxes to find (e.g. functional response22). At very low densities, nests may experience some relief from fox predation as foxes switch to other prey22, and at least a limited recovery of the population via juvenile recruitment may be possible, until nest abundance is again high enough for foxes to target. It is also possible that the numbers of turtles we caught are too low to accurately reflect population size structures, particularly at Clayton Bay and Lake Eppalock.
Our age structure analysis for C. longicollis did not detect strong geographic or climatic differences. Large adult turtles (>220 mm SCL) were much more common than juveniles within pond habitats, but we detected no other differences. Ponds had relatively large numbers of C. longicollis, so it is possible that high densities of turtle nests might attract higher levels of fox predation on eggs at these sites22, which would reduce recruitment. Alternatively, some of the ponds included in our sampling completely dry occasionally, and it is possible that hatchling and juvenile turtles are less able to avoid the impacts of wetland drying than are adults, via estivation or migration, though this has not previously been reported52. In contrast to E. macquarii, we caught relatively high numbers of juvenile C. longicollis at some lagoon, lake, and tributary habitats throughout the Murray catchment. In another study, C. longicollis juveniles were rare during the Millennium Drought (1996–2010) in the lower Murrumbidgee River, but have been caught with increasing frequency since 201351. Together, these results suggest that C. longicollis populations experience unique patterns in juvenile recruitment, and are not as consistently at risk of population aging as are E. macquarii. The ability of C. longicollis to migrate long distances overland to exploit temporary wetland habitats52,53 may allow a greater degree of terrestrial dispersal of turtles of all age groups than occurs in other species, which could buffer against population aging. The same migratory ability may also have allowed adult C. longicollis to persist in environments that experienced drying during the Millennium Drought, especially Serpentine Weir.
Together, our data provide evidence for regional declines in freshwater turtles in the Murray River catchment. All three species were detected at low numbers, relative to trapping effort, throughout most of South Australia, but E. macquarii populations appear to be at particular risk. Although relatively more abundant at many locations further upstream, E. macquarii may be at risk of a collapse even at many of these sites because the majority of E. macquarii populations are heavily biased to older females, and juvenile turtles are uncommon. These size structures may be caused by low rates of recruitment. Low recruitment may be due to high rates of fox predation on nests, or to changes to the environments that hatchlings require once they reach the water. Incubating and hatching eggs in captivity to avoid foxes altogether would test the role of foxes in the decline, following Spencer and Thompson15. If recruitment improved after release of captive-incubated hatchlings at multiple sites along the Murray River, then foxes might be assumed to be the major cause of turtle losses in recruitment at a landscape scale. Alternatively, if released hatchlings were not recaptured and recruitment remained low even after hatchling release, then other factors, like macrophyte loss, food web disruption, or water quality issues, may be responsible for low recruitment rates. It is also possible that low CPUE is caused by both lack of recruitment and by high adult mortality. The causes of the decline thus require additional study.
Despite turtle declines in South Australia being predicted 30 years ago, that prediction was not followed by extensive study or successful management of freshwater turtles. If further surveys show continued declines in turtles, a major vertebrate guild responsible for considerable nutrient and mineral cycling in the aquatic ecosystem48,63, could eventually become extinct. Our results suggest that reassessments of the conservation status and management plans of these species are needed. Emydura macquarii is listed as Vulnerable in both South Australia and Victoria, and Chelodina expansa is listed as Vulnerable in South Australia and Endangered in Victoria, but none of these species are listed in New South Wales. Furthermore, none are listed at the federal level. By contrast, C. longicollis is widespread away from the major waterways of the Murray River system, and further assessments are needed to examine its status away from the catchment, where our study was focused. Finally, it is worth noting that, despite the many threats they face, freshwater turtles are sometimes considered resilient taxa because many species are able to survive in poor quality habitats where other taxa cannot64,65,66,67,68.
Long-lived species like turtles are often neglected as at-risk species in need of conservation action, due to the “perception of persistence”63. Even in species with relatively high abundance, low rates of recruitment may be catastrophic once the majority of individuals present die of old age63. Often it is only when populations crash or a crash is imminent that they become listed for conservation action, yet the life history of long-lived species means that they give us considerable warning. In turtles from the Murray River, this population crash was predicted almost 30 years ago, and our data indicate that it is in progress.
We assessed turtle populations at 52 sites throughout the southern Murray River catchment in January-April of 2015–2017 (Fig. 4). January-April in the Murray region coincides with consistently warm and dry weather and high turtle activity50. It is after the spring nesting season for C. longicollis and E. macquarii, but overlaps with the autumn nesting season of C. expansa. All upper Murray sites (river km 1730–2600) were assessed in Jan, 2016; mid-Murray sites (river km 1125–1730) in Feb-Mar, 2015 and 2016; and lower Murray sites (river km 19–570) in Jan-early Mar, 2017. Only 2 sites were assessed in early April, 2016: Wentworth and Euston, but maximum air temperatures at these sites exceeded 30 °C and turtles were active. Most, but not all, of our sites were chosen because they were on opposite sides of a dam, weir, or impoundment, to contribute data to a concurrent study on genetic connectivity among E. macquarii populations (Berman et al. unpubl. data), but were not near the dam or in a weir pool itself. Notably, we did not survey much of the upper Murray (Fig. 4; near Albury, NSW) because of pre-existing data of the concurrent genetic study, which used a different survey method (Berman et al. unpubl. data).
We included a range of wetland types in our assessment, and included sites associated with the Murray River itself, tributaries to the Murray River, and anabranches in the Murray River catchment. We defined wetland types by their physical characteristics: backwaters are unrestricted embayments broadly connected to the main channel of a river or lake; lagoons are embayments that are narrowly connected to the main channel of another, larger water body; lakes are sites trapped near the open shoreline of a large natural lake or large reservoir/impoundment; ponds are small wetlands disconnected from any adjacent waterway; streams are small fast-flowing upland waterways with rocky bottoms; and tributaries are large slow-flowing waterways with sand or mud bottoms.
Our trapping schedule evolved over time. To meet the requirements of our concurrent genetic study (Berman et al. unpubl. data), we initially aimed to trap at each site until at least 30 E. macquarii were caught. In our initial trapping in 2015, we were sometimes able to catch 30 E. macquarii using only 3–4 traps at a time overnight, which resulted in high CPUE relative to low trapping effort at Burramine and Ovens (Fig. 1). As our trapping progressed to other locations, our catch rates decreased. Thus, to balance trapping effort with trapping at as many sites as possible, at the majority of sites we used at least 10 traps at a time, set for at least three overnight periods or until we caught at least 25 E. macquarii. We switched to 25 minimum E. macquarii rather than 30 because in some cases we caught between 25 and 30 E. macquarii within 2 nights, and we decided it was more productive to move traps to another site in our survey to ensure we trapped all sites before the active season ended.
There were several exceptions to this rule due to extraneous circumstances. Landowners of Raukkan-Narrung, Banrock Station, Alexandra, Malmsbury, and King River were only able to allow us access for 1-2 nights, and there were limited sites suitable for setting our traps due to high currents and shallow water at Malmsbury and King River. Our sites in Benalla, Tullaroop, and Cairn Curran had anglers present after 1-2 nights, so we removed traps to prevent them from being stolen, which occurred several times early in our study. Finally, we had a side project at Lake Bonney that allowed us to trap there for 2 weeks (Cameron et al., unpublished data). In overnight trap sessions, we typically set traps in the evening of the first day, and removed traps on the morning of the final day (overall mean trap effort: 576 ± 58 trap-hours, Fig. S1). We acknowledge that our approach is probably too short to determine whether turtles are absent from a site, and do not consider an absence of detection as an absence of turtles. Instead, our aim was to determine a relative index of turtle population characteristics that could be compared across the catchment.
We used three different turtle trap types: cathedral traps, single-wing fyke traps, and crab pots. We used a variety of traps because each trap type is not equally suited to use in every type of habitat. Cathedral traps are best suited for still water >1.4 m deep, while fyke traps are best suited for still or slow-moving water <1 m deep, and crab pots are best suited for very shallow, slow-moving water <0.2 m deep. At most sites, we used at least 10 traps, and usually mixed trap types (3-4 each), while trapping a site (maximum 25). We set cathedral traps in open, still water deeper than 1 m. We set fyke traps in open water 0.2–0.5 m deep, with the wing of the fyke parallel to the nearest shoreline. We set crab pots in water ~0.2 m deep, sometimes nestled within benthic vegetation. Despite their differences, each trap type is capable of catching at least 10 turtles at a time. When trapping in fast-flowing streams, we always placed traps in or on the edge of deeper pools, where currents slowed as much as possible. All traps were baited with a mix of offal (lamb heart, lamb liver, chicken liver). Traps were checked twice per day and were re-baited once per day.
Upon checking traps, we removed any turtles present and immediately re-set the trap, and re-baited it if necessary. After removing turtles from traps, we checked them for existing carapace marks to determine whether they were recaptures, from our own or previous studies69. We recorded the identifications of turtles recaptured within the trapping session and immediately released them. Occasionally, we caught turtles that had been marked by a previous study, potentially up to 40 years earlier e.g., Chessman; Thompson9,33. We recorded these turtles’ existing IDs, but considered them novel to our current analyses. We weighed all turtles to the nearest 1 g on a digital scale. We measured straight carapace length and width with forestry callipers. We marked all unidentified turtles individually by notching their marginal scutes69. We recorded the sex of each turtle where possible. The tails of adult and subadult C. expansa and E. macquarii are sexually dimorphic and longer in males. The tails of adult C. longicollis are only slightly sexually dimorphic and other diagnostics are not universally reliable, so we did not record sexes of C. longicollis47. All work was conducted under OEH permit SL101639, DPI permit P09/0070-20, DEWNR Permit M26597-1, DEWLP permit 10007501, DEPI permit RP1225, and Western Sydney University Animal Ethics Committee Animal Research Authority A10455.
We analyzed two metrics of turtle population status at each site: catch-per-unit-effort (CPUE) and the proportions of juvenile and large adult turtles of each species. Both metrics were analyzed separately for each species. We used CPUE as a relative index of local abundance to assess the number of turtles present in a site whilst accounting for trapping effort produced by our design. Because we caught at least 25 E. macquarii at some sites very rapidly, our trapping effort at those sites was relatively small, whereas our trapping effort was larger at sites where we caught turtles at a slower rate. We compared CPUE of each species across sites using log-linear Analyses of Covariance with Poisson distributions (PROC GLIMMIX) in SAS University Edition (SAS Institute, Cary, NC). We accounted for trapping effort by multiplying the number of traps set by the number of hours they were set, disregarding trap type, and including this value as a covariate. We specified wetland type as an independent variable to test for CPUE differences among wetland types, and approximate river distance on the Murray River (distance in km from the river mouth, hereafter referred to as River Distance) as a covariate to test for geographic differences across the Murray Catchment. In this design, multiple sites sampled from the same tributary (e.g., Loddon River) were assigned the same river distance, because the confluence between the tributary and the Murray River was the same for all. We also included distance from the nearest permanent water body (km), distance from the Murray River, mean annual precipitation (mm) and mean air temperature (°C) to test for environmental and climatic effects on turtle CPUE across the catchment. Distance data were extracted from Google EarthTM. Climate data were extracted from Worldclim (Ver. 2, www.worldclim.org)70, using location averages to within 30 seconds of latitude/longitude spatial resolution, from 1970–2000. We log-transformed all numerical data in this analysis. Because of the wide variation in trapping effort across sites (Fig. S1), we tested for robustness in our results by running an identical model without sites that had fewer than 100 total trap-hours for any reason, and also without Lake Bonney, because it was an outlier with very high trapping effort. For presentation of the data, we also calculated CPUE by summing the number of turtles caught by all traps at a site and dividing by the number of trap-hours (number of traps multiplied by number of hours traps were set). We calculated CPUE separately for each species, and did not distinguish among sex, body size, or trap type.
We used the numbers of juveniles and large adults, relative to total number caught, as metrics of recent recruitment and population aging, because both drought and fox destruction of nests have been suggested to drive losses of recruitment, which may result in population collapses if adults are not replaced as they die of old age9,33,48. Furthermore, size-structure bias toward smaller (younger) or larger (older) turtles may suggest different stressors affecting population dynamics, e.g. low recruitment or population bottlenecks. At any site where we caught at least five turtles of a given species, we counted the numbers of juveniles of each species, using straight-carapace length (SCL), following Chessman33,47. The maximum cutoff for juvenile SCL was 220 mm for C. expansa, 180 mm for C. longicollis, and 190 mm for E. macquarii. We also counted the number of large adults of each species using arbitrary cutoffs: 350 mm for C. expansa, 230 mm for C. longicollis, and 250 mm for E. macquarii.
Within each site, we tested for differences in the relative numbers of juveniles and large adults using log-linear Analyses of Covariance with Poisson distributions (PROC GLIMMIX) for each species. We included the total number of turtles caught at each site as a covariate to account for differences in the numbers of turtles caught. We included “sex” (juvenile, large female, large male; or juvenile, large adult in C. longicollis) to test for differences in the numbers of each group. As in the CPUE analysis, we included river distance, distance from the Murray River, distance from the nearest permanent water, wetland type, mean annual temperature, and mean annual precipitation to assess geographic and climate relationships in the numbers of juveniles and large adults. We also included the interaction sex*wetland type to test whether numbers of juveniles and large adults differed uniquely within each wetland type. Finally, we included site as a random effect to account for repeated within-site comparisons across sexes. We also calculated percentages of juveniles, large females, and large males (or large adults for C. longicollis) at each site in order to present the data clearly. In all analyses, we determined statistical significance at 0.05 type I error level, and we present data as means ± SE.
The datasets generated during and/or analysed during the current study are available from the corresponding author on reasonable request.
Ceballos, G. et al. Accelerated modern human–induced species losses: Entering the sixth mass extinction. Science Advances 1, e1400253 (2015).
Dirzo, R. et al. Defaunation in the anthropocene. Science 345, 401–406 (2014).
Barnosky, A. D. et al. Has the Earth’s sixth mass extinction already arrived? Nature 471, 51–57 (2011).
Lister, B. C. & Garcia, A. Climate-driven declines in arthropod abundance restructure a rainforest food web. Proceedings of the National Academy of Sciences, https://doi.org/10.1073/pnas.1722477115 (2018).
Purvis, A., Gittleman, J. L., Cowlishaw, G. & Mace, G. M. Predicting extinction risk in declining species. Proceedings of the Royal Society B, Biological Sciences 267, 1947–1952 (2000).
Keith, D. A. et al. Predicting extinction risks under climate change: coupling stochastic population models with dynamic bioclimatic habitat models. Biology Letters 4, 560–563 (2008).
Brook, B. W., Sodhi, N. S. & Bradshaw, C. J. A. Synergies among extinction drivers under global change. Trends Ecol. Evol. 23, 453–460 (2008).
Martin, T. G. et al. Acting fast helps avoid extinction. Conservation Letters 5, 274–280 (2012).
Thompson, M. B. Populations of the Murray River Tortoise, Emydura (Chelodina): the effect of egg predation by the Red Fox, Vulpes vulpes. Aust. Wildl. Res. 10, 363–371 (1983).
Rhodin, A. G. J. et al. Turtles in Trouble: The World’s 25+ Most Endangered Tortoises and Freshwater Turtles—2011. (Turtle Conservation Coalition, IUCN/SSC, Lunenburg, MA, USA, 2011).
Colteaux, B. C. & Johnson, D. M. Commercial harvest and export of snapping turtles (Chelydra serpentina) in the United States: trends and the efficacy of size limits at reducing harvest. Journal of Nature Conservation 35, 13–19 (2017).
Gong, S. et al. Disappearance of endangered turtles within China’s nature reserves. Curr. Biol. 27, R170–R171 (2017).
Beaudry, F., DeMaynadier, P. G. & Hunter, M. L. Jr. Identifying road mortality threat at multiple spatial scales for semi-aquatic turtles. Biol. Conserv. 141, 2550–2563 (2008).
Langen, T. A., Gunson, K. E., Scheiner, C. A. & Boulerice, J. T. Road mortality in freshwater turtles: identifying causes of spatial patterns to optimize road planning and mitigation. Biodivers. Conserv. 21, 3017–3034 (2012).
Spencer, R.-J. & Thompson, M. B. Experimental analysis of the impact of foxes on freshwater turtle populations. Conserv. Biol. 19, 845–854 (2005).
Heinrich, G. L., Walsh, T. J., Jackson, D. R. & Atkinson, B. K. Boat strikes: a threat to the Suwannee Cooter (Pseudemys concinna suwanniensis). Herpetological Conservation and Biology 7, 349–357 (2012).
Lum, L. L. Assessment of incidental sea turtle catch in the artisanal gillnet fishery in Trinidad and Tobago, West Indies. Applied Herpetology 3, 357–368 (2006).
Limpus, D. J., Limpus, C. J. & Hodge, W. J. Marine and Freshwater Sciences Environmental Sciences Division. Conservation Technical and Data Report 7, 1–15 (2006).
Steen, D. A., Hopkins, B. C., Van Dyke, J. U. & Hopkins, W. A. Prevalence of ingested fish hooks in freshwater turtles from five rivers in the southeastern United States. PLoS One 9, e91368 (2014).
Steen, D. A. & Robinson, O. J. Jr. Estimating freshwater turtle mortality rates and population declines following hook ingestion. Conserv. Biol. 31, 1333–1339 (2017).
Tomillo, P. S., Saba, V. S., Piedra, R., Paladino, F. V. & Spotila, J. R. Effects of illegal harvest of eggs on the population decline of leatherback turtles in Las Baulas Marine National Park, Costa Rica. Conserv. Biol. 22, 1216–1224 (2008).
Spencer, R. J., Van Dyke, J. U. & Thompson, M. B. The ‘Ethological Trap’: Functional and numerical responses of highly efficient invasive predators driving prey extinctions. Ecol. Appl. 26, 1969–1983 (2016).
Rhymer, J. M. & Simberloff, D. Extinction by hybridization and introgression. Annu. Rev. Ecol. Syst. 27, 83–109 (1996).
Georges, A., Spencer, R. -J., Killian, A. & Zhang, X. Assault from all sides: hybridization and introgression threaten the already critically endangered Myuchelys georgesi (Chelonia: Chelidae). Endangered Species Research, https://doi.org/10.3354/esr00928 (2018).
Spencer, R. J., Georges, A., Lim, D., Welsh, M. & Reid, A. M. The risk of inter-specific competition in Australian short-necked turtles. Ecol. Res. 29, 767–777 (2014).
Moloney, B., Britton, S. & Matthews, S. Bellinger River snapping turtle mortality event 2015: epidemiology report. (NSW Department of Primary Industries, 2015).
Cann, J., Spencer, R. J., Welsh, M. & Georges, A. Myuchelys georgesi (Cann 1997) – Bellinger River Turtle. Chelonian Conserv. Biol. 5, 1–9 (2015).
Spencer, R. J. et al. Profiling a possible rapid extinction event in a long-lived species. Biol. Conserv. 221, 190–197 (2018).
Johnson, A. J. et al. Ranavirus infection of free-ranging and captive box turtles and tortoises in the United States. J. Wildl. Dis. 44, 851–863 (2008).
Brown, M. B. et al. Upper respiratory tract disease in the gopher tortoise is caused by Mycoplasma agassizii. Journal of Clinical Microbiology 37, 2262–2269 (1999).
Schwanz, L. E. & Janzen, F. J. Climate change and temperature-dependent sex determination: can individual plasticity in nesting phenology prevent extreme sex ratios. Physiol. Biochem. Zool. 81, 826–834 (2008).
Gibbons, J. W., Greene, J. L. & Congdon, J. D. Drought-related responses of aquatic turtle populations. J. Herpetol. 17, 242–246 (1983).
Chessman, B. C. Declines of freshwater turtles associated with climatic drying in Australia’s Murray-Darling Basin. Wildl. Res. 38, 664–671 (2011).
Bower, D. S., Hutchinson, M. & Georges, A. Movement and habitat use of Australia’s largest snake-necked turtle: implications for water management. J. Zool. (Lond.) 287, 76–80 (2012).
Bower, D. S., Death, C. E. & Georges, A. Ecological and physiological impacts of salinisation on freshwater turtles of the lower Murray River. Wildl. Res. 39, 705–710 (2012).
Bower, D. S. et al. Salinity tolerances of two Australian freshwater turtles, Chelodina expansa and Emydura macquarii (Testudinata: Chelidae). Conservation. Physiology 4, cow042 (2016).
Van Dyke, J. U., Hopkins, W. A. & Jackson, B. P. Influence of relative trophic position and carbon source on selenium bioaccumulation in turtles from a coal fly-ash spill site. Environ. Pollut. 182, 45–52 (2013).
Bergeron, C. M., Husak, J. F., Unrine, J. M., Romanek, C. S. & Hopkins, W. A. Influence of feeding ecology on blood mercury concentrations in four species of turtles. Environ. Toxicol. Chem. 26, 1733–1741 (2007).
Hopkins, B. C., Willson, J. D. & Hopkins, W. A. Mercury exposure is associated with negative effects on turtle reproduction. Environ. Sci. Technol. 47, 2416–2422 (2013).
Van Dyke, J. U., Beck, M. L., Jackson, B. P. & Hopkins, B. C. Interspecific differences in egg production affect egg trace element concentrations after a coal fly ash spill. Environ. Sci. Technol. 47, 13763–13771 (2013).
Ferronato, B. O., Roe, J. H. & Georges, A. Reptile bycatch in a pest-exclusion fence established for wildlife reintroductions. Journal for Nature Conservation 22, 577–585 (2014).
Ferronato, B. O., Roe, J. H. & Georges, A. Urban hazards: spatial ecology and survivorship of a turtle in an expanding suburban environment. Urban Ecosyst. 19, 415–428 (2016).
Brooks, R. J., Brown, G. P. & Galbraith, D. A. Effects of a sudden increase in natural mortality of adults on a population of the common snapping turtle (Chelydra serpentina). Can. J. Zool. 69, 1314–1320 (1991).
Spencer, R.-J., Van Dyke, J. U. & Thompson, M. B. Critically evaluating best management practices for preventing freshwater turtle extinctions. Conserv. Biol. 31, 1340–1349 (2017).
Keevil, M. G., Brooks, R. J. & Litzgus, J. Post‐catastrophe patterns of abundance and survival reveal no evidence of population recovery in a long‐lived animal. Ecosphere 9, e02396 (2018).
Robley, A. et al. The effectiveness of short-term fox control in protecting a seasonally vulnerable species, the Eastern Long-necked Turtle (Chelodina longicollis). Ecol. Manag. Restor. 17, 63–69 (2016).
Chessman, B. C. Ecological studies of freshwater turtles in south-eastern Australia., Monash University (1978).
Thompson, M. B. In Herpetology in Australia (eds D. Lunney & D. Ayes) 219–224 (Surrey Beatty and Sons, 1993).
Van Dyke, J. U., Ferronato, B. & Spencer, R. J. Current conservation status of Australian freshwater turtles. Aust. J. Zool. 66, 1–3 (2018).
Chessman, B. C. Habitat preferences of fresh-water turtles in the Murray Valley, Victoria and New South Wales. Wildl. Res. 15, 485–491 (1988).
Ocock, J. F. et al. Identifying critical habitat for Australian freshwater turtles in a large regulated floodplain: implications for environmental water management. Environ. Manag. 61, 375–389 (2017).
Roe, J. H. & Georges, A. Terrestrial activity, movements and spatial ecology of an Australian freshwater turtle, Chelodina longicollis, in a temporally dynamic wetland system. Austral. Ecol. 33, 1045–1056 (2008).
Roe, J. H. & Georges, A. Maintenance of variable responses for coping with wetland drying in freshwater turtles. Ecology 89, 485–494 (2008).
Spencer, R.-J., Janzen, F. J. & Thompson, M. B. Counterintuitive density-dependent growth in a long-lived vertebrate after removal of nest predators. Ecology 87, 3109–3118 (2006).
Kingsford, R. T. Ecological impacts of dams, water diversions and river management on floodplain wetlands in Australia. Austral. Ecol. 25, 109–127 (2000).
Koehn, J. D. Carp (Cyprinus carpio) as a powerful invader in Australian waterways. Freshw. Biol. 49, 882–894 (2004).
Petrov, K., Lewis, J., Malkiewicz, N., Van Dyke, J. U. & Spencer, R. J. Food abundance and diet variation in freshwater turtles from the mid-Murray River, Australia. Aust. J. Zool. 66, 67–76 (2018).
Skinner, D., Oliver, R., Aldridge, K. & Brookes, J. Extreme water level decline effects sediment distribution and composition in Lake Alexandrina, South Australia. Limnology 15, 117–126 (2014).
Morrongiello, J. R., Crook, D. A., King, A. J., Ramsey, D. S. L. & Brown, P. Impacts of drought and predicted effects of climate change on fish growth in temperate Australian lakes. Global Change Biology 17, 745–755 (2011).
Kingsley, T. -A. In ABC Central Victoria, http://www.abc.net.au/local/stories/2007/05/01/1910984.htm (2007).
Humphries, P. Loddon-Campaspe drought response options – environmental flow management. (North Central Catchment Management Authority, Bendigo, VIC, Loddon River Environmental Flows Panel, 2006).
Spencer, R.-J. Growth patterns of two widely distributed freshwater turtles and a comparison of common methods used to estimate age. Aust. J. Zool. 50, 477–490 (2002).
Lovich, J. E., Ennen, J. R., Agha, M. & Gibbons, J. W. Where have all the turtles gone, and why does it matter? Bioscience, https://doi.org/10.1093/biosci/biy1095 (2018).
Stokeld, D., Hamer, A. J., van der Ree, R., Pettigrove, V. & Gillespie, G. Factors influencing occurrence of a freshwater turtle in an urban landscape: a resilient species? Wildl. Res. 41, 163–171 (2014).
Jergensen, A. M., Miller, D. A. W., Neuman-Lee, L. A., Warner, D. A. & Janzen, F. J. Swimming against the tide: resilience of a riverine turtle to recurrent extreme environmental events. Biology Letters 10, 20130782 (2014).
Mitchell, J. C. Population ecology and life histories of the freshwater turtles Chrysemys picta and Sternotherus odoratus in an urban lake. Herpetol. Monogr. 2, 40–61 (1988).
Lamb, T., Bickham, J. W., Lyne, T. B. & Gibbons, J. W. The slider turtle as an environmental sentinel: multiple tissue assays using flow cytometric analysis. Ecotoxicology 4, 5–13 (1995).
Hopkins, B. C., Hepner, M. J. & Hopkins, W. A. Nondestructive techniques for biomonitoring of spatial, temporal, and demographic patterns of mercury bioaccumulation and maternal transfer in turtles. Environ. Pollut. 177, 164–170 (2013).
Cagle, F. R. A system of marking turtles for future identification. Copeia 1939, 170–173 (1939).
Hijmans, R. J., Cameron, S. E., Parra, J. L., Jones, P. G. & Jarvis, A. Very high resolution interpolated climate surfaces for global land areas. International Journal of Climatology 25, 1965–1978 (2005).
This work was supported by ARC Linkage grant (LP140100011) awarded to R.S., A.D., B.C. and M.T. Partners included Foundation for National Parks and Wildlife, North Central Catchment Management Authority, Yorta Yorta Nation Aboriginal Corporation, Department of Environment and Primary Industries, Winton Wetlands Committee of Management Inc. and Save Lake Bonney Group Inc. Our work would not have been possible without the cooperation of landowners throughout the Murray River catchment. We especially acknowledge the Traditional Owners and Custodians of the land, past and present. We especially thank I. Campbell, L. Dodd, C. Johnson, K. Kropinyeri, W. Mark, and S. Rigney of the Ngarrindjeri People, Geoff Braddock, D. Smith, J. Tesoreiro (SA NRM), C. Toureng (Banrock Station Winery), T. Broster (Save Lake Bonney), Dr. P. Cale (Calperum Station), S. Scown (Paiwalla Wetland), D. Tyack, P. and K. Doyle, S. Modra, R. Brunsworthy, A. Martin and J. James (North Central CMA), Ridley Agriproducts, Y Water Discovery Centre, Deniliquin Clay Target Club, Kelly Brothers Farm, Crotty family, J. and M. Paul (Dockers Plains Pastoral Company), de Bortoli Wines, and Goulburn-Murray Water for providing access to their properties and offering assistance. B. Ferronato, K. Petrov, I. Bleach, M. Huson, M. Johnson, H. Campbell, J. Farquhar, H. Donovan, and T. Williams and her class (Bendigo TAFE) provided field assistance. We thank G. Stockfeld, D. Hill, and J. Pike (Turtles Australia) for their considerable help in fieldwork and in developing local contacts throughout Victoria. We thank 3 anonymous reviewers for their comments on the manuscript.
The authors declare no competing interests.
Publisher’s note: Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
About this article
Cite this article
Van Dyke, J.U., Spencer, R.–., Thompson, M.B. et al. Conservation implications of turtle declines in Australia’s Murray River system. Sci Rep 9, 1998 (2019). https://doi.org/10.1038/s41598-019-39096-3
Hatchling short-necked turtles (Emydura macquarii) select aquatic vegetation habitats, but not after one month in captivity
Aquatic Ecology (2021)
Demographics and morphometrics of marsh terrapins (Pelomedusa galeata) and serrated hinged terrapins (Pelusios sinuatus) populations in KwaZulu-Natal, South Africa: skewed size-class bias concerns
Prey-switching does not protect a generalist turtle from bioenergetic consequences when its preferred food is scarce
BMC Ecology (2020)
Scientific Reports (2020)
Where are the turtles when they are not? Underwater refuges used by Hydromedusa tectifera COPE, 1869 in a suburban stream
Urban Ecosystems (2020)